KR100419485B1 - Apparatus for suppling a power for an IC card - Google Patents

Abstract

The power supply device for IC card and the control method thereof according to the present invention accumulate an extra charge in a charge storage circuit when driving a card in an IC card system in which a battery is built, and use it again for a low power consumption operation such as a standby state. The power consumption of the system can be minimized. Also, when the charge accumulated in the charge storage circuit is used at the time of transition from the low power consumption operation such as the standby state to the normal operation state, the operation state of the card system changes. By absorbing the sudden voltage changes that can be applied to the card system, it enables an efficient and stable power supply.

Description

Power supply for IC card {Apparatus for suppling a power for an IC card}

The present invention relates to an IC card system, and more particularly, to a power supply device for an IC card. That is, the present invention relates to a device and a method for preventing battery consumption due to leakage current generated when driving an IC card system circuit through charge recycling. The present invention relates to a power supply device for an IC card and a control method thereof for minimizing power consumption of an internal power source by using accumulated electric charges when not used and direct operation such as a standby state.

In general, IC cards contain important information such as user secret keys, personally identifiable information, key codes, etc., and are used in many applications due to the advantage of providing higher security than conventional magnetic tape cards.

IC cards are divided into contact cards powered by a card reader and non-contact cards powered by an electromagnetic induction principle. These IC cards have in common that they are externally powered to drive the internal circuits of the card.

Recently, hacking of a card system has been frequently performed for the purpose of dedicating user information inside such an IC card. Hacking behavior for IC card system can be divided into active (physical) hacking and passive hacking.

First, active or physical hacking refers to a method of collecting and analyzing internal data by actually contacting the chip surface after removing a physical protection device that protects the cryptographic module inside the IC card. On the other hand, passive hacking is a method of inferring internal information by analyzing an operation performed in a cryptographic module by applying power from the outside or applying a glitch signal without modifying the IC card system itself.

Passive hacking on the IC card uses the characteristic that power must be applied from the outside in order to operate the card system as described above. The method is used to analyze the response time of an operation.

As an alternative to such a hacking method, a method of preventing the aforementioned passive hacking using a card system with a built-in battery has recently been proposed.

Hereinafter, a brief description will be made of a general IC card system.

FIG. 1 is a block diagram illustrating a general IC card system. Referring to FIG. 1, a block configuration of the IC card system includes a power supply circuit unit 100 and an internal circuit unit 200.

The internal circuit unit 200 may include a memory 220 for storing information, a cryptographic processor 230 which is an encryption-only auxiliary processor, an interface 270 for communicating with the outside, a timing circuit unit 260 for generating a clock signal, and the like. In addition, the security sensor circuit unit 240 performing the intrusion probe function, the reset signal generator 280 for generating a reset signal according to the signal of the security sensor circuit unit 240, generates a random number necessary for use of the public key or secret key, etc. The random number generating circuit unit 210, the processor 250 as a central computing unit, and the interrupt generator 29 for generating an interrupt signal are included. Here, the memory 220, the cryptographic processor 230, the interface 270, the timing circuit unit 260, and the processor 250 are connected to each other by a bus for transmitting data to each other.

In addition, the power supply unit 100 of the IC card system supplies the driving power to the internal circuit 200 and controls all functions in the power supply. The power supply unit 100 is mounted inside the card, and the power supply unit 100 inside the card provides power for driving the circuit system 200 inside the card system. The power supply unit 100 supplies a variable voltage or current according to the operating state of the card internal circuit 200. However, subdividing the range of voltages that can be supplied also limits the implementation of the circuits, making it impossible to form the voltage at any desired stage.

In particular, if the card is operating normally but waiting for an external signal, the card system requires an extremely low level of voltage, but in practice the voltage level used in the card system does not provide a sufficiently low voltage level. In addition, the conventional IC card system with a built-in battery has a problem that it is difficult to efficiently use the built-in power supply because the system continuously supplies more voltage than necessary by the continuous voltage application.

Accordingly, the present invention has been made to solve the above-mentioned problems according to the prior art, an object of the present invention, to minimize the power consumption required to drive the system in the IC card system with an internal power supply (battery) and stable operation The present invention provides an IC card power supply and a control method thereof.

1 is a block diagram showing a general IC card system.

2 is a block diagram showing a power supply device for an IC card according to the present invention;

3 is a flowchart illustrating an operation of a power supply method for an IC card according to the present invention;

* Description of the symbols for the main parts of the drawings *

100: power supply circuit unit 110: internal power

120: switching control circuit portion 130: charge accumulation circuit portion

140, 141: switching unit 200: internal circuit

In order to achieve the above object, the present invention provides a charge circulation circuit in a power supply unit inside an IC card system, and configures a switching stage capable of cross-selecting the original power supply unit and the charge circulation circuit stage to operate the card system. According to the feature it can be selectively supplied with power.

That is, a feature of the IC card power supply device according to the present invention is an IC card system comprising a battery and an internal circuit, comprising: accumulating means for accumulating and supplying power supplied from the battery to the internal circuit; Switching switching so that the power supplied from the battery can be accumulated in the storage means, the battery power can be supplied to the internal circuit, or the power stored in the storage means can be supplied to the internal circuit according to the switching control signal provided. Way; And switching control means for providing a switching control signal to the switching means according to the driving mode of the card system to control the battery power or the power stored in the storage means to be supplied to the internal circuit.

The switching control means may be configured to: a) provide a switching control signal to the switching means such that when the card system is in the operation mode, the battery power is accumulated in the storage means and the battery power is supplied to the internal circuit. B) blocking the supply of battery power when the card system is in the standby mode as a result of the determination of the mode determining unit, and providing a switching control signal to the switching means so that the power accumulated in the accumulation means can be supplied to the internal circuit. and c) a switching path setting unit configured to control switching of the switching means in the same manner as the operation mode when the amount of charge accumulated in the accumulation means detected from the charge amount detector in the standby mode is equal to or less than a preset threshold.

In addition, the switching control means includes a time setting section for allowing the accumulation means to accumulate periodically for a predetermined time during charge accumulation, and for setting the charge amount detection period from the charge amount detection means, wherein the accumulation means is hardware In general, a single device or a combination of several devices.

The switching means includes: a first switching unit connected to the battery, the accumulation means, and the internal circuit, respectively, for setting a path of power supply to the internal circuit according to a switching control signal provided from a switching control means; A second switching unit connected to the accumulating means and the ground and the internal circuit and configured to accumulate charge and supply power to the internal circuit according to a switching control signal provided from a switching control means; Selection devices such as demultiplexers or the like / encoder / decoder and switching elements.

On the other hand, the feature of the IC card power supply method according to the present invention, the power supply method of the IC card system having a battery and a charge accumulator connected to the battery and an internal circuit to the power supply, the driving mode of the card system Determining; a) supplying the battery power to the driving circuit when the card system is in the current operation mode and accumulating charges; and b) storing the accumulated charge when the card system is in the standby mode. Establishing a power supply path to be supplied to the internal circuit; Detecting the accumulated charge amount while the accumulated charge is supplied to an internal circuit; And when the detected charge amount is less than or equal to a preset threshold, supplying the battery power to an internal circuit and accumulating battery power in the charge accumulator.

Hereinafter, a power supply device for an IC card and a control method thereof according to the present invention will be described in detail with reference to the accompanying drawings.

FIG. 2 is a block diagram illustrating a power supply device for an IC card according to an embodiment of the present invention. Referring to FIG. 2, an internal power supply (battery) 110, a switching control circuit unit 120, and charge accumulation are described. The circuit unit 130 and the first and second switching units 140 and 141 are configured, and the first and second switching units 140 and 141 are connected to the internal circuit unit 200, respectively.

The internal power source 110 is a battery, and supplies a predetermined level of power when the mode of the internal circuit unit 200 of the card system is in an operation mode or a standby mode.

The switching control circuit unit 120 receives a mode determination signal from a mode determination unit that determines a current state of the card system, that is, whether the card system is in an operation mode or a standby mode, from a mode determination unit (not shown) in the internal circuit unit 200. After that, the switching control signal is provided to the first switching unit 140 and the second switching unit 141 according to the received mode determination signal.

That is, when the current card system is in the operation mode, the switching control circuit unit 120 allows the internal power source 110 to be supplied to the internal circuit unit 200 and at the same time, the internal power source 110 supplies the charge accumulation circuit unit 130. The switching control signal is provided to the first switching unit 140 to be accumulated.

In addition, the switching control circuit unit 120 provides a switching control signal to the second switching unit 141 to accumulate charge in the charge accumulation circuit unit 130. That is, the switching control circuit unit 120 switches the second switching unit 141 to ground so as to control the internal power (charge) to be accumulated in the charge accumulation circuit unit 130. As a result, when it is determined that the card system is in the operation mode, the switching control circuit 120 may supply the internal power to the internal circuit 200 and at the same time, charge may be accumulated in the charge accumulation circuit 130. 140, 141 will be controlled.

On the other hand, when the determination signal provided from the mode determining unit in the internal circuit unit 200 is a standby mode signal, that is, when the current card system is in the standby mode, the switching control circuit unit 120 may generate charges stored in the charge accumulation circuit unit 130. The switching control signal is provided to the first switching unit 140 to be supplied to the internal circuit unit 300. That is, in the standby mode, the internal power is blocked from being supplied to the internal circuit unit 200, and the charge accumulated in the charge accumulation circuit unit 130 may be supplied to the internal circuit unit 200.

In addition, the switching control circuit unit 141 provides a switching control signal to the second switching unit 141 to control the charge accumulation circuit unit 130 to be connected to the internal circuit unit 200.

At this time, while the charge accumulated in the charge accumulation circuit unit 130 is being supplied to the internal circuit unit 200, the switching control circuit unit 120 detects the amount of charge accumulated in the charge accumulation circuit unit 130.

As a result of the detection, when the amount of charge accumulated in the charge accumulation circuit unit 130 is equal to or greater than the preset reference value, the control is performed so that the accumulated charge is continuously supplied to the internal circuit unit 200. By providing a switching control signal to the first switching unit 140 and the second switching unit 141 to control the internal power supply to the internal circuit unit 200. That is, when the accumulated charge amount is less than or equal to the reference value, the first and second switching units 140 and 140 may be configured to supply the internal power to the internal circuit unit 200 and to accumulate the charge in the charge accumulation circuit unit 130 in the same manner as in the operation mode. 141). In this case, the switching control circuit unit 120 continuously detects the amount of charge accumulated in the charge accumulation circuit unit 130, and when all the electric charges are accumulated above a predetermined reference value or in the storage capacity, the first and second switching units 140 and 141 are returned. To control the first and second switching units 140 and 141 so that the charge accumulated in the charge accumulation circuit unit 130 can be supplied to the internal circuit unit 200.

As a result, the first switching unit 140 is switched according to the switching control signal provided from the switching control circuit unit 120 to set the supply path of the internal power, and may be composed of one or a plurality of switching elements. It is obvious that not only switching devices but also combinations of multiplexers such as multiplexers and demultiplexers such as demultiplexers can be combined.

In addition, the second switching unit 141 connects the charge accumulation circuit unit 130 with the internal circuit unit 200 or sets a path for accumulating charge, and like the first switching unit 140, the switching control circuit unit ( 120). That is, the first and second switching units 140 and 141 perform complementary operations to set the path of the charge accumulation circuit unit 130.

Then, the charge accumulation circuit unit 130 accumulates the power provided from the internal power supply or supplies the accumulated charge to the internal circuit according to the current operating state of the card system. In addition, the charge accumulation circuit unit 130 is a comprehensive representation of a device capable of accumulating charge, and may be implemented inside the card system or separately outside the card system using a single element.

A detailed operation of the power supply device for an IC card according to the present invention having such a configuration will be described.

First, when the card system is in the normal operation mode, that is, when the mode determination signal input from the mode determination unit in the internal circuit unit 200 is the normal operation mode signal, the switching control circuit unit 120 may switch between the first switching unit 140 and the second. Each of the switching units 141 provides a switching control signal.

In other words, when the card system is in the normal operation mode, the switching control circuit unit 120 supplies the internal power source 110 to the internal circuit and at the same time the internal power source is accumulated in the charge accumulation circuit unit 130. ) Provides a switching control signal. Therefore, the internal circuit unit 200 is driven through the provided internal power supply.

In addition, the switching control circuit unit 120 provides a switching control signal to the second switching unit 141 to control switching to ground so that the internal power is accumulated in the charge accumulation circuit unit 130. That is, when the first switching unit 140 is set to the internal power supply, the second switching unit 141 is switched to ground to accumulate charge in the charge accumulation circuit unit 130, in which case the second switching unit 141 is The connection with the internal circuit 200 is to be disconnected.

In addition, when the card system requires low power, the switching control circuit unit 120 controls the first switching unit 140 and the second switching unit 141 to convert the charge accumulation circuit unit 130 into a charge accumulation mode so as to supply internal power. Will accumulate.

When the card system is in the normal operation mode as described above, while the charge is accumulated in the charge accumulation circuit unit 130, the switching control circuit unit 120 continuously detects the amount of charge accumulated in the charge accumulation circuit unit 130.

As a result of the detection, when the amount of charge accumulated in the charge accumulation circuit unit 130 is accumulated in the storage capacity, the first and second switching units 140 and 141 are controlled to prevent the internal power supply from being supplied to the charge accumulation circuit unit 130. do. At this time, the internal power is continuously supplied to the internal circuit unit 200.

Here, in the switching control circuit unit 120, as described above, when the charge amount of the charge accumulation circuit unit 130 is periodically checked to decrease below the preset threshold value, the first and second switching units 140 and 141 and the electric charge are charged. It may include a monitoring device for controlling the accumulation circuit unit 130 to accumulate the charge, and also set a time to set the predetermined time to periodically accumulate the charge in the charge accumulation circuit unit 130 It may include a device.

In the above, the case in which the card system is in the operation mode has been described. Hereinafter, the operation in the case in which the card system is in the standby mode will be described.

First, when the card system is in the standby mode waiting for an external signal, that is, when the mode determination signal input from the mode determination unit in the internal circuit unit 200 is the standby mode signal, the switching control circuit unit 120 may be connected to the first switching unit 140. The switching control signal is provided to the second switching unit 141, respectively. That is, when the card system is in the standby mode, the switching control circuit unit 120 supplies the switching control signal to the first and second switching units 140 and 141 so that the charge accumulated in the charge accumulation circuit unit 130 is supplied to the internal circuit unit 200. The first switching unit 140 cuts off the connection between the internal power source 110 and the internal circuit unit 200 according to the switching control signal provided from the switching control circuit unit 120, and the charge accumulation circuit unit 130. The internal circuit unit 200 is switched to be connected. Therefore, the internal circuit unit 200 is driven by the power supplied from the charge accumulation circuit unit 130. In this case, the second switching unit 141 is also switched to connect the charge accumulation circuit unit 130 connected to the ground with the internal circuit unit 200 according to the switching control signal provided from the switching control circuit unit 120. Therefore, the charge accumulated in the charge accumulation circuit unit 130 may be normally supplied to the internal circuit unit 200.

As described above, when the card system is in the standby mode, the switching control circuit unit 120 periodically detects the amount of charge stored in the charge accumulation circuit unit 130. When the detected charge amount is greater than or equal to a preset threshold, the switching control circuit unit 120 The first and second switching units 140 and 141 may be supplied to the internal circuit unit 200, and in contrast, when the amount of charge currently accumulated is less than or equal to a preset threshold, the first and second switching units 140 and 141 may be supplied to the internal circuit unit 200. ) Provides a switching control signal.

That is, the switching control circuit unit 120 provides a switching control signal to the first switching unit 140 when the amount of charge accumulated in the charge accumulation circuit unit 130 is less than or equal to the threshold value, thereby providing the charge accumulation circuit unit 130 and the internal circuit unit 200. ) And control the internal power supply to the internal circuit unit 200 by connecting the internal power supply and the internal circuit unit 200, and simultaneously connect the internal power supply and the charge accumulation circuit unit 130 to supply the internal power supply. The charge is accumulated in the charge accumulation circuit unit 130.

In addition, the switching control circuit unit 120 provides a switching control signal to the second switching unit 141 to disconnect the charge accumulation circuit unit 130 from the internal circuit unit 200 and to connect the charge accumulation circuit unit 130 to ground. Internal power is accumulated in the charge accumulation circuit unit 130.

While the charge is accumulated, the switching control circuit unit 120 detects the amount of charge accumulated in the charge accumulation circuit unit 130. When it is detected that all of the charge is accumulated in the storage capacitor, the switching control circuit unit 120 again performs the first and second operations. The switching units 140 and 141 are controlled to control the charges accumulated in the charge accumulation circuit unit 130 to be supplied to the internal circuit unit 200. That is, the connection between the internal power supply and the internal circuit unit 200 is interrupted and the charge accumulation circuit unit 130 and the internal circuit unit 200 are connected. Here, the connection between the internal power supply and the charge accumulation circuit unit 130 is also cut off.

In addition, the switching control circuit unit 120 provides a switching control signal to the second switching unit 141 to connect the charge accumulation circuit unit 130 connected to the ground to the internal circuit unit 200.

The switching control circuit unit 120 prioritizes two signals generated by monitoring a signal indicating an operation state of the card system in the card system and the amount of charge accumulated in the charge accumulation circuit unit 130, and thus, effectively converts the first and second signals. 2 to control the switching unit (140, 141).

As a result, the power supply device for the IC card according to the present invention controls the first and second switching units 140 and 141 when the card system is in the operation mode, thereby controlling the internal power to be supplied to the internal circuit unit 200 and simultaneously charging the electric power. The charge is controlled to be accumulated in the accumulation circuit unit 130, and when the card system is in the standby mode, the charge accumulated in the charge accumulation circuit unit 130 instead of the internal power source may be supplied to the internal circuit unit 200. In this case, when the amount of charge accumulated in the charge accumulation circuit unit 130 in the standby mode is less than the threshold value, the first and second switching units 140 and 141 are controlled in the same manner as in the operation mode to supply the internal power supply to the internal circuit unit. While controlling to be supplied to the 200, the internal power is accumulated in the charge storage circuit 130.

In addition, when charge accumulation is completed in the charge accumulation circuit unit 130 like the sound in the standby mode, the operation is switched back to the above-described standby mode again so that the charge accumulated in the charge accumulation circuit unit 130 is supplied to the internal circuit unit 200. As a result, the internal circuit unit 200 is driven.

Hereinafter, a power supply method for an IC card according to the present invention corresponding to the operation of the power supply device for an IC card as described above will be described step by step with reference to the accompanying drawings.

3 is a flowchart illustrating an operation of a power supply method for an IC card according to the present invention.

First, the operation state of the card system is grasped (S101).

Subsequently, it is determined whether the card system is in the operation mode (S201), and when the card system is in the operation mode, the first and second switching units 140 and 141 are controlled to supply the internal power to the internal circuit unit 200. (S103). Therefore, the internal circuit unit 200 is operated by using the internal power source.

In addition, the switching control circuit unit 120 controls the first and second switching units 140 and 141 so that the internal power is supplied to the internal circuit unit 200 and accumulated in the charge accumulation circuit unit 130 (S104).

However, when it is determined in operation S102 that the card system is determined to be in the standby mode, the first and second switching units 140 and 141 may supply the charge stored in the charge accumulation circuit unit 130 to the internal circuit unit 200. ) Is controlled (S105).

As such, while the charge is supplied from the charge accumulation circuit unit 130 to the internal circuit unit 200, the switching control circuit unit 120 detects the amount of charge accumulated in the charge accumulation circuit unit 130 at a predetermined cycle (S106).

Subsequently, the detected charge amount is compared with a preset threshold value (S107). That is, when the detected charge amount is larger than the preset threshold value, the charge accumulated in the charge accumulation circuit unit 130 is used as a driving power source of the internal circuit unit 200. It will be supplied (S108).

However, when the amount of charge detected in the step S107 is less than the predetermined threshold value to feed back to step S103 to control the first and second switching unit 140, 141 so that the internal power can be supplied to the internal circuit unit 200. will be.

When the first and second switching units 140 and 141 are switched, the internal power is supplied to the internal circuit unit 200 as a driving power and simultaneously supplied to the charge accumulation circuit unit 130 to accumulate charge. While the charge is accumulated, the switching control circuit unit 120 continuously or periodically checks the amount of charge accumulated in the charge accumulation circuit unit 130, and when the accumulated charge amount is accumulated in the accumulation circuit unit 130 as a pool, the switching control circuit unit 120 The first and second switching units 140 and 141 are controlled to cut off the power supplied from the internal power supply to the internal circuit unit 200 and the charge accumulation circuit unit 130, and the charge accumulation circuit unit 130 to the internal circuit unit 200. It will be controlled to be supplied.

As a result, the power supply device and control method for the IC card according to the present invention prevents battery consumption due to leakage current generated when the internal circuit is driven through recycling. If you use an internal power supply and do not operate directly with a card reader, such as in a standby state, you can use the accumulated charge to minimize the power consumption of the internal power supply.

The power supply device and control method for an IC card according to the present invention as described above is to accumulate extra charge in the charge storage circuit when the card is driven in the battery-embedded IC card system, and to re-use it to a low power consumption such as a standby state. Because of this advantage, the power consumption of the card system can be minimized.

In addition, since the charge accumulated in the charge storage circuit is used at the point of transition from the low power consumption operation such as the standby state to the normal operation state, a sudden voltage change that may be applied to the card system when it changes with the operation state of the card system. It has the effect of enabling efficient and stable power supply.

Claims (12)

delete delete In an IC card system comprising a battery and an internal circuit, Accumulating means for accumulating power supplied from the battery and supplying the internal circuit; Switching switching so that the power supplied from the battery can be accumulated in the storage means, the battery power can be supplied to the internal circuit, or the power stored in the storage means can be supplied to the internal circuit according to the switching control signal provided. Way; Switching control means for providing a switching control signal to the switching means according to the driving mode of the card system to control the battery power or the power stored in the storage means to be supplied to an internal circuit; The switching control means, A mode determination unit that determines whether the driving mode of the card system is an operation mode or a standby mode; A charge amount detector for detecting an amount of charge accumulated in the accumulation means, The switching control means, a) when the card system is in the operation mode as a result of the determination of the mode determining unit, providing a switching control signal to the switching means such that the battery power is accumulated in the storage means and the battery power can be supplied to the internal circuit; b) as a result of the determination of the mode determining unit, when the card system is in the standby mode, cuts off the supply of battery power and provides a switching control signal to the switching means so that the power accumulated in the accumulation means can be supplied to the internal circuit; and c) a switching path setting unit for switching and controlling the switching means in the same manner as the operation mode when the amount of charge accumulated in the accumulation means detected from the charge amount detection unit is less than or equal to a predetermined threshold value in a standby mode. . The method of claim 3, The switching control means, And a time setting section for allowing the accumulation means to accumulate periodically for a predetermined time during charge accumulation, and for setting a charge amount detection period from the charge amount detection means. The method of claim 3, The accumulation means, A power supply for an IC card that consists of a single device or a combination of devices that are hardware independent. The method of claim 3, The switching means, A first switching unit connected to the battery, the accumulation means, and the internal circuit, respectively, for setting a path of power supply to the internal circuit according to a switching control signal provided from a switching control means; And a second switching unit connected to the accumulating means and the ground and the internal circuit and configured to accumulate electric charge and supply power to the internal circuit according to a switching control signal provided from the switching control means. The method of claim 3, The switching means, A power supply for an IC card comprising a selection device such as a multiplexer, a demultiplexer, or an encoder / decoder and a switching element. The method of claim 3, The switching path setting unit, A power supply device for an IC card for setting the path of the switching means by giving priority to the operation mode of the card system and the amount of charge accumulated in the accumulation means. The method of claim 3, The accumulation means, Power supply for IC cards that can be implemented separately inside or outside the card system. delete delete delete